FI85312B - ANORDINATION FOR GRANSKNING AV SEDLARS AUTHENTICITY. - Google Patents

Abstract

Bank notes can be checked for authenticity using apparatus which examines properties of the note which are the same in different spatial orientations. In particular, the entire surface area of at least one side of a bank note (1) can be subjected to spectral analysis, using light radiation reflected from or transmitted through the note. The received radiation can be integrated over the entire surface area and then compared, using a microprocessor-based system (6), with stored spectral models corresponding to different kinds of bank notes. An algorithm may be used which is capable of allowing for deviations due, for example, to soiling of a bank note.

Description

1 85312

Device for checking the authenticity of banknotes

FIELD OF THE INVENTION This invention relates to an apparatus for authenticating banknotes.

The trend towards less labor-intensive methods of distributing merchandise using automatic vending machines for products such as petrol, cigarettes and foodstuffs has led to an increase in 10 interest in the automatic authentication of banknotes. The arrival of cheap microprocessors on the market has now made it possible to implement an advanced segregation criterion and offers the possibility to design vending machines that accept banknotes of different values and even currencies. The increased use of vending machines, especially for larger banknotes, naturally also increases the risk of large-scale fraud and therefore emphasizes the need for a sufficient banknote authentication criterion.

20 Technical background

The patent literature explains various methods of banknote authentication, some of which are used in currently commercially available vending machines. Validation methods and verification algorithms are known, for example, from U.S. Patent No. 2,950,799, DE Patent Specification No. 1,774,344, and SE Patent Specification No. 7,606,828. sensory methods.

In the first class of authentication methods, sensors are used to measure the thickness distribution in some specific parts of the banknote, corresponding to different details of the banknote, where the thickness varies due to the printing process, watermarks, etc. The correct 2 85312 indicator criterion is then based on a comparison with explicit standard values. The thickness is measured with mechanical or optical sensors. Mechanical sensors for measuring thickness are known, for example, from GB patents 960,391, 963,586, DE patents 1,474,903, 2,423,094, AT patents 329,903, SE patents 337,952, 357,636, 349,679 and 7,607. 927-6. Optical methods for correcting are known, for example, from DE patent descriptions 10 2 005 016 and 2 365 845. Combined mechanical and optical sensors are described, for example, in SE patent specification 361 372.

Examples of another class of authentication are shown in U.S. Patent No. 2,646,717 and SE Patent Specification No. 196,238, in which a pattern in a selected portion of a banknote is compared to a standard pattern by observing the modulation that occurs when these patterns are superimposed and shifted relative to each other.

In the third class of authentication methods, a banknote is illuminated and the reflection and / or transmission properties of selected parts of the banknote are examined using corresponding sets of detectors, one for each part, which respond differently to the spectrum (e.g. U.S. Patent No. 3,491,243). Alternatively, selected portions of the banknote are illuminated with a plurality of light sources, one for each portion and having different spectral distributions, respectively, and then the transmission and / or reflection characteristics are compared to standard values as a basis for verification (e.g., U.S. Patent Nos. 3,450,785 and 3,679,314). ).

With regard to the three main categories of authentication methods described above, the following observations are made.

• _ Insofar as the thickness criterion is closely related to the printing process, it has the advantage that it can be more difficult

II

3 85312 pi circumvents by fraudulent means other than a criterion based on patterns or colors. On the other hand, the corrugations or other imperfections that arise in the normal rejection of a banknote cause large rejection rates of genuine but used banknotes, especially if optical thickness measurements are used. Known mechanical sensors tend to be quite expensive and require considerable maintenance to ensure proper operation.

Of the three categories considered, the pattern recognition method is probably the most unsatisfactory, as it may be easy to obtain copy patterns with commercially available copying methods that can be distinguished from the original patterns only by microscopic examination. models.

Third-class color tests probably represent the best compromise between simplicity of structure and satisfactory separation of fraud. However, the known structures of this class 20 have not fully utilized the information provided by the spectrum in that sensors with a relatively wide spectral sensitivity have been used.

In all known devices of the categories described above, only specific selected parts of the banknotes 25 are used in the discrimination criterion. This means that the banknote must be placed relatively accurately in the device, and the resolution depends on the accuracy of such placement. Also, the printing processes of the banknotes are anything but accurate, and the position of the printing relative to the edges 30 often varies. In addition, if the logical advantages of microprocessors were to be fully exploited in the context of a known device for constructing vending machines that accept multiple values and even different currencies, trade-offs would potentially have to be made in selecting the parts of the banknotes to which the criteria apply. -TA.

Disclosure of the Invention It is an object of the present invention to provide a device with which banknotes can be authenticated easily and expediently and yet with satisfactory accuracy and in which the rejection rate of real banknotes is not unreasonably high.

According to the invention, there is therefore provided a device 10 for correcting banknotes by examining their light reflection or transmission properties at different wavelengths, comprising a research area for receiving a banknote, means for transmitting light of different wavelengths towards a Sete-15 in the research area, which can be used to analyze light reflected from or transmitted to the banknote and thus generating corresponding electrical signals representing the characteristics of the banknote, a comparator arranged to compare the data derived from said electrical signals-20 with stored reference data related to at least one real banknote and to produce an output signal indicating or not, in which case the device may be used to integrate the studied characteristics of the banknote into different parts of the surface 25 which is characterized by the analyzer being arranged to integrate transmitted or reflected light from the entire surface of the banknote on at least one side thereof, all parts of the surface being geometrically equivalent, and analyzing said integrated light as a function of different wavelengths in strong spectral resolution so that the device can be used reliably regardless of banknote orientation research in the area.

With this arrangement, it is possible, due to the use of an analysis method that is at least certain

II

5 85312 independent of the spatial direction of the banknote, achieves satisfactory authentication accuracy in a simple and appropriate manner and without a disproportionately high rate of rejection of genuine banknotes.

Said analyzer is preferably used to examine most of the surface of the banknote, preferably completely or substantially completely on at least one side of the banknote, and with a view to eliminating the effect of the space structure of the banknote, the studied features are preferably integrated over the entire surface of the banknote. The loss of data due to said integration is an advantage rather than a downside, as it can usually eliminate a space structure with a very high level of detail that is difficult to deal with adequately. Instead, analyzer-15 rin printing may contain data that is easier to process. In the invention, it is not necessary to place the banknotes in the device in a precisely predetermined manner, but it may even be possible to place the banknote upside down or in any direction without compromising the authenticity test. In addition, it may also be possible to test different types of banknotes (different values and currencies) with the same optimum accuracy.

The analyzer is preferably a spectrum analyzer that can be used for the spectral distribution of radiation from a multi-wavelength radiation source reflected or transmitted by the banknote. If necessary, a sensing device responsive to the selected wavelengths can be used in the analyzer, either as an interference filter or as a series of separate monochromatic filters in conjunction with a sensor or sensors that can be used to provide electrical signals at such wavelengths.

BRIEF DESCRIPTION OF THE DRAWING The present invention will now be described in more detail with reference to the accompanying drawing, which is a schematic representation of one aspect of a device according to the invention.

35 6 35312

The best way to practice the invention

The device is intended to be used to authenticate a conventional banknote printed with a detailed color pattern of one or more colors or shades.

The device can be connected to a vending machine or used as needed in any context. The device comprises a chamber 10 into which the banknote 1 to be authenticated is fed using a suitable feeding device 10.

As shown in the drawing, the banknote 1 is fed into the evaluation area 2 of the chamber 10, where it is placed against a black background 3 and where it is illuminated by light sources 4 (e.g. wire lamps) with a uniform spectral distribution-15 ma. The optical sensor 5 receives light reflected from the entire upper surface of the banknote. The optical beam of the optical sensor 5 is wide enough and placed at a sufficient distance from the banknote 1 to combine the partial reflections from the entire surface of the banknote without giving substantially 20 geometric priority to any part of the banknote. The optical sensor 5 converts the received light into spectral data with strong spectral resolution, and this data is fed in the form of electrical signals to a microprocessor-based monitoring system 6.

The optical sensor can be implemented in several alternative embodiments. In principle, a prism or a folding lattice can be used. For economic and practical reasons, interference filters are more preferred either in the form of a continuous interference filter in which the bandpass wavelength changes along the filter, or in the form of a separate set of monochromatic filters. Electrical signals representing spectral information are obtained either by moving the filter / filter array in front of a single detector or by using multiple detectors behind the filter / filter array 35. Depending on the desired wavelength sensitivity may

II

7 85312 detectors be silicon, germanium or lead sulphide detectors.

From an economic point of view, it is even more advantageous to use light emitting diodes (LEDs) as a spectral venture. The LEDs 5 detect radiation in the same way as ordinary light emitting diodes, but only in a narrow spectral range which is approximately the same as that in which they emit light.

Instead of the light source with a uniform spectral distribution and monochromatic detectors described above, an inverse arrangement of the monochromatic light sources and the detector or detectors having a uniform spectral sensitivity can be used. The light sources can be activated alternately one after the other in a rapid sequential order. In this order, the banknote is preferably illuminated with a series of 15 LEDs, so that only LEDs of the same spectral type are lit at the same time. By storing the data obtained from the detector in relation to the operating times of the LEDs, the necessary spectral data can be obtained.

The locked switch can be used to selectively operate the device in one of two ways, by programming and evaluating, for authentication. When programming, the microprocessor considers the new banknote inserted in the evaluation area of each device to be a comparison and stores the corresponding spectral data in memory. In this way, the reference spectrum of the various banknotes can be derived and stored permanently. When the locked switch is set to the evaluation mode, the spectrum of each new banknote entered into the evaluation area of the device is compared with the reference spectrum in the memory. This comparison is made by a comparison algorithm in which the spectral values of the test voucher 30 at different wavelengths are compared with the corresponding values of each reference spectrum. In order to prepare for possible fouling, etc., the algorithm may comprise a free normalization parameter. Since fouling and other defects due to the use of banknotes 35 only cause a change in the overall reflectance, etc., 8 85312 the deviation thus formed in real banknotes is usually small and this authentication technique accurately distinguishes real banknotes from false ones.

Appropriate feeding devices may be available to transfer the authenticated banknote from the chamber 5 to the storage location while the vending machine dispensing mechanism is activated, and to transfer the non-authenticated banknote to return removal or the like.

As already mentioned, the integrated correctness criterion used in the above-mentioned 10 devices can estimate different values and / or different currencies with the same optimum accuracy. This requires that the full logical capacity of the included microprocessor can be used to check the banknotes compared to a large number of reference spectra for both the front and back, different metamers, etc., corresponding to different values and currencies, for example. It is particularly important that there is sufficient storage space available to check the different metamers of the banknotes, i.e. the different color pigments that look the same but have a different spectral composition. Although most metameric differences are the result of fraud, the color pigments of genuine banknotes are changed from time to time, and this can be taken into account in the programming of the device described above.

The invention is not intended to be limited to the details of the embodiment described above, which are explained only by way of example. Therefore, for example, it is possible to study the entire transmission spectrum of the banknote instead of or to supplement the reflection spectrum discussed above. To complete the separation, a wide spectral range extending from ultraviolet to infrared (190 to about 3000 nm) can also be used for evaluation purposes, in which information on both the color pigment and the composition and structure of the paper can be obtained.

35 Fiberglass can be used to save space

II

9 85312 or plexiglass light guides for transferring light between the banknote and the sensor / light source. In this way, a much smaller embodiment can be achieved. The light guides also provide a simple way to obtain more information about the banknote in the form of certain additional integrals of the whole banknote, such as thermal ohmic changes or moments, preferably combined with the spectral data described above.

Claims (10)

An apparatus for correcting banknotes by examining their light reflection or transmission properties at different wavelengths, the apparatus comprising a test area (2) for receiving a banknote (1), means for transmitting light of different wavelengths towards a banknote (1) in the test area (2), an analyzer (5) , which can be used to analyze light reflected from or transmitted by said banknote and thus generate corresponding electrical signals representing the characteristics of the banknote, a comparator (6) arranged to compare the data derived from said electrical signals with stored reference data related to at least one real banknote and to produce a printing signal indicating whether the examined banknote is correct or not, whereby the device can be used to integrate the examined features of the banknote into different parts of its surface, characterized in that the analyzer (5) is arranged to integrate t or reflected light over the entire surface of the banknote (1) on at least one side, all parts of the surface being geometrically equivalent, and analyzing said integrated light as a function of different wavelengths in strong spectral resolution so that the device can be reliably detected regardless of banknote orientation and position in the research area (2). Device according to one of Claims 1, characterized in that the analyzer (5) is a spectral analyzer which can be used to analyze the reflection or penetration of radiation from a variable wavelength radiation source (4) from the banknote (1). Device according to Claim 1, characterized in that the analyzer (5) is a radiation detector with a broad spectrum of 11 8531 2 which can be used to receive radiation reflected from or transmitted through the banknote (1) from a series of substantially monochromatic radiation sources (4). , which are activated alternately in successive 5th order. Device according to claim 2, characterized in that the analyzer (5) comprises an interference filter in which the substantially monochromatic bandpass wavelength can be changed continuously along the filter 10. Device according to claim 2, characterized in that the analyzer (5) comprises a plurality of substantially monochromatic sensors, each of which has an interference filter with a fixed, narrow band and a bandpass wavelength separate for each air i. S i me 11e. Device according to claim 2, characterized in that the analyzer (5) comprises a plurality of sensors, each of which is provided with a light emitting diode 20 used as a detector with a fixed, narrow bandwidth and a bandpass wavelength different for each detector. Device according to one of Claims 1 to 6, characterized in that the uniform illumination and the reception of the radiation 25 are obtained by having the radiation source (4) and the analyzer (5) at a sufficient distance from the examination area (2). Device according to one of Claims 1 to 6, characterized in that the uniform illumination and the reception of the radiation 30 are obtained in a small space so that the radiation propagates through light guides. Device according to one of Claims 1 to 8, characterized in that the comparator (6) comprises a microprocessor-based system using a reference algorithm which can be used to identify a country banknote (1) of a certain type as a genuine banknote, if the absolute norm of the spectral shape of the banknote under examination in comparison with the reference spectral shape of said type of banknote does not exceed a specific value, as well as in the other case-5 for rejecting the banknote as incorrect. Device according to claim 9, characterized in that said comparison algorithm comprises a free normalization parameter which allows the comparison to be insensitive to, for example, contamination of the banknote (1). 10 li i3 8531 2